# About MIT 6.00 course lec06--Newton's method

I have tried to code in my own way, but found I got the wrong answer.

f(x)=x^2-e

The math:

So there is my code:

``````def sqrtRootNR(num, count, epsl):
"""
for test
"""
num = float(num)
guess = num / 2.0
diff = guess ** 2.0 - num
_cnt = 0
while abs(diff) > epsl and _cnt < count:
guess = guess - (guess ** 2.0 + epsl) / (guess * 2.0)
diff = guess ** 2.0 - num
_cnt = _cnt +1
print guess, _cnt

sqrtRootNR(2, 100, 0.0001)
``````

However, I got the wrong answer.

The output of this function is:

D:\poc>python sq.py

0.0595177826557 100

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What answer did you get? What answer did you expect? Did you print out intermediate values? Did they correspond with your manual calculations? – Oliver Charlesworth Dec 9 '11 at 2:25
What is `f(x)`. Is it `f(x)=sqrt(x)` and you are solving for `f(x)=num` ? – ja72 Dec 9 '11 at 2:44

Change `(guess ** 2.0 + epsl)` to `(guess ** 2 - num)` in your equation. You want to adjust your estimate every step by an amount proportional to your error, ie. your `diff` variable.

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One important skill in programming is knowing which information where will be most useful. If you add some simple debugging information:

``````while abs(diff) > epsl and _cnt < count:
guess = guess - (guess ** 2.0 + epsl) / (guess * 2.0)
diff = guess ** 2.0 - num
print guess, _cnt
_cnt = _cnt +1
print guess, _cnt
``````

You can see that your program goes wrong quickly:

``````\$ ./sqrt.py
0.49995 0
0.249874989999 1
0.124737394941 2
0.0619678553654 3
0.0301770577385 4
0.0134316410297 5
0.00299326718803 6
-0.0152075217183 7
-0.00431591416548 8
0.00942707405618 9
-0.000590335594744 10
....
``````

It appears to halve the number every iteration until it goes negative, when the behavior gets very difficult to tell just at a glance. But you can obviously tell that the very first few iterations are wrong.

Something that looks quite fishy to me: `(guess ** 2.0 + epsl)`

You shouldn't actually use epsilon when evaluating Newton's method for square roots -- after all, you're trying to make sure your error is less than epsilon.

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It looks like you are looking for zeroes of the function f = x^2+eps1. If eps1 is positive, there will be no real zeroes. This means that your program will oscillate around 0 forever after a certain point, as you saw. If you set eps1 to a negative value, I expect you would find a root.

Newton's method isn't bullet-proof, and there are cases where it can diverge.

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You also can use `guess = 0.5 * (guess + num/guess)`

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